KR102082148B1 - Solar power generating system and method having an automatic fire extinguisher - Google Patents

Abstract

The present invention relates to a photovoltaic system having a fire extinguishing system using gas, capable of accurately determining a fire occurred and rapidly extinguishing the fire using fire extinguishing gas, and a method thereof. According to the present invention, the photovoltaic system having a fire extinguishing system using gas comprises: a plurality of solar cell arrays; a fuse unit; a high-voltage PCB having a voltage measuring unit and a current measuring unit; a gas fire extinguishing system; a gas storage tank; a valve; a spraying system; a circuit breaker; an inverter; and a monitoring system.

Description

Solar power generating system and method having an automatic fire extinguisher with gas fire extinguishing system

The present invention relates to a photovoltaic power generation system equipped with a gas-based fire extinguishing system and a method thereof, and more specifically, to accurately determine a fire that may occur in a connection panel of a photovoltaic power generation system equipped with a gas-based fire extinguishing system, A gas for efficient and safe management of the solar power generation system by providing a fire extinguishing system that uniformly injects fire extinguishing gas inside the connection panel by keeping the spray pressure of the nozzle constant by keeping the distance the fire extinguishing gas moves in the event of a fire. The present invention relates to a solar power generation system equipped with a fire extinguishing system and a method.

In the components of the photovoltaic power generation device, there is always a risk of fire because equipment, such as inverters and connection panels, generates a lot of heat due to high voltage and high current, and is often installed outdoors. Suppression is not easy. Considering that the initial extinguishing is very important within 1 minute from the time of ignition in the event of a fire, it is easy to spread to a large fire in an instant in case of ignition inside the connection panel because these facilities are connected to other facilities. Therefore, there is an urgent need for a means to quickly extinguish the fire in the event of a fire in the connection panel.

Patent No. 10-1572608 “Solar power generation system with automatic fire extinguishing function” has a cooling fan that can induce the circulation of internal and external air inside the connection panel in the photovoltaic power generation system, preventing the inside of the connection panel from overheating And, when a fire occurs, the fire extinguishing tube is operated quickly to provide a solar power generation system with automatic fire extinguishing.

However, in the fire extinguishing agent selected for the purpose of extinguishing or spraying over a wide area, there is a problem that damage to the electronic and electric devices inside the connection panel may occur.

Registered Patent No. 10-1313901 “Monitoring device of solar panel equipped with fire extinguishing unit” easily detects the flame of the connection panel and extinguishes it quickly, and it is possible to quickly identify and maintain the abnormality of the solar panel. Provide a monitoring device.

However, in the case of a connecting panel made of mostly solid combustible material, it is possible to dehydrate and burn without burning a flame, so there is a problem in that fire monitoring using a flame is difficult.

Registered Patent No. 10-1920065 “Solar connection panel with electric fire detection function” is configured to detect abnormality by constructing a detection unit that can detect temperature, CO, flame, condensation and moisture inside the solar connection panel. It provides a solar connection panel with an electric fire detection function. It also provides a photovoltaic connection panel with an electric fire monitoring function that acquires information using the detection panel and generates an event signal according to whether there is a fire or an abnormality and transmits it to a remote terminal.

However, it has a similar problem to the aforementioned patents. In addition, since temperature detection uses a constant temperature algorithm, it can be judged as a fire only when the temperature above the set temperature is measured.

Korean Registered Patent Publication No. 10-1313901 Korean Registered Patent Publication No. 10-1572608 Korean Registered Patent Publication No. 10-1920065

The present invention was made to solve the above problems, and when a fire occurs in a photovoltaic device, it is accurately and quickly determined as the conditions of temperature detection and smoke detection, and temperature detection is a constant temperature and differential temperature detection algorithm The object of the present invention is to provide a photovoltaic power generation system equipped with a fire extinguishing system using a gas to detect a temperature change inside the connection panel and to extinguish a fire generated by using fire extinguishing gas when a fire occurs.

In addition, an object of the present invention is to provide a solar power generation system equipped with a gas-based fire extinguishing system and a method for minimizing damage to electronic and electrical devices inside a connection panel due to fire extinguishing agents using fire extinguishing gas.

In addition, in the case of a nozzle for spraying fire extinguishing gas, the object of the present invention is to provide a solar power generation system and a method provided with a fire extinguishing system using the gas uniformly sprayed inside the connection panel by making the distance of travel of the extinguishing gas the same. .

The object of the present invention is not limited to the above-mentioned object, other objects and advantages of the present invention which are not mentioned can be understood by the following description, and will be more clearly understood by embodiments of the present invention. In addition, it will be readily appreciated that the objects and advantages of the present invention can be realized by means of the appended claims and combinations thereof.

The present invention for achieving the above object is a plurality of solar cell array that generates a DC voltage and generates a current; A fuse unit in which DC voltages generated by the plurality of solar cell arrays are merged and supplied to an inverter and connected in series to each input / output terminal of the plurality of solar cell arrays; A high voltage PCB having a voltage measuring unit measuring voltage at each output terminal of the fuse and a current measuring unit measuring current at each output terminal of the fuse; The temperature sensor inside the connection panel measures the temperature inside the connection panel, the smoke sensor detects smoke generated inside the connection panel, and determines the fire through the high temperature, abnormal heating condition, and smoke detection determined by the internal temperature. A gas fire extinguishing system for extinguishing a fire by the judgment of the communication device and the control unit and the communication device and control unit for generating a control signal for opening and closing the valve and alerting the user of the city valve; A gas storage tank in which gas used for extinguishing is stored in the gas extinguishing system; A valve for opening and closing between the gas storage tank and the injection system according to the control signals of the communication device and the control unit in the gas fire extinguishing system; An injection system for injecting extinguishing gas at a uniform pressure into the connection panel in the gas extinguishing system; A circuit breaker blocking a closed circuit between the solar cell array and the inverter; An inverter that converts DC current supplied from the connection panel into AC current; It includes; a monitoring system for monitoring the operation status and the presence or absence of the solar cell array, the connection panel and the inverter.

The communication device and control unit transmits data on the output of the photovoltaic device and the state of the connection panel to the monitoring system based on the smoke detection and abnormal heat generation or the high temperature state, and the abnormal state determined by the calculation unit ( High temperature, abnormal heat, smoke detection), the monitoring system controls the opening and closing of the valve existing between the gas storage tank and the injection system, and controls the temperature and If it is determined that a fire has occurred inside the connection panel based on the smoke data, it is characterized in that it comprises a control unit that controls to open the valve to extinguish the fire.

The calculating unit determines the high temperature state by using the constant temperature algorithm for the internal temperature measured inside the connection panel, calculates the temperature change rate by using the differential algorithm for the measured internal temperature, and determines abnormal heat, and the inside of the connection panel by the smoke detector. It is characterized by determining the abnormal state according to whether smoke is generated, and determining the fire based on smoke detection and abnormal heat or high temperature.

The injection system is characterized in that the pressure from each nozzle is uniformed by maintaining the same distance from the gas storage tank to the injection nozzle so that fire extinguishing gas can be injected at a uniform pressure inside the connection panel.

It is installed around the plurality of solar cell arrays to obtain temperature information and solar radiation information, and further comprises a meteorological observation panel that transmits the obtained weather information to the monitoring system.

In the case of using the Y fitting, the injection system uses a tube made of heat-resistant and fire-resistant materials, and the inside of the tube has the same cross-sectional area and maintains a constant distance from the gas inlet to the nozzle of the injection system.

The present invention is another embodiment measuring the data and calculating the risk step (S100); Determining whether the abnormal condition (danger level is 1) is correct (S200); As a result of the determination in step S200, if an abnormal condition (dangerous step is 1) is correct, generating a device alarm and a monitoring warning window (S300); As a result of the determination in step S200, determining whether the fire occurrence state (dangerous step 2) is correct if the abnormal state (dangerous step is 1) (S400); As a result of the determination in step S400, if it is not a fire occurrence state (dangerous stage 2), determining a normal state (dangerous stage 0) (S500); As a result of the determination in step S400, when a fire occurrence state (dangerous step 2) is correct, generating a device alarm, a monitoring warning window, and a warning sound (S600); Opening a valve located between the gas storage tank and the injection system (S700); Injecting the extinguishing gas through the injection system (S800); And transmitting a message for the dangerous step 2 to the manager (S900).

When the internal temperature of the connection panel is a measurement sequence number (tn), the measured temperature (Tn), the measurement sequence number and the measured temperature in a one-to-one correspondence step S1; S2 step of setting a constant temperature type (Tf) and a differential temperature change rate (Tr) for warning when a temperature-related abnormality occurs in the connection panel; Step S3 for measuring the internal temperature (T ') with a temperature sensor installed inside the connection panel; n increases from 1, the measurement sequence number (tn) is set to n step S4; Step S5 of storing the measured temperature T 'in Tn; Step S6, determining whether the measured temperature Tn is greater than or equal to the set constant temperature temperature Tf; As a result of the determination in step S6, when the measured temperature Tn is less than the set constant temperature temperature Tf, the procedure is performed in step S18, which is a normal state (dangerous step 0), and the measured temperature Tn is the set constant temperature. When the temperature is greater than or equal to the temperature (Tf), step S7 for determining the inside of the connection panel as a high temperature state; Step S8 to determine whether the measurement sequence number n is greater than 5; As a result of the determination in step S8, when n is equal to or less than 5, step S9 of increasing the measurement sequence n by 1; As a result of the determination in step S8, if n is greater than 5, step S10 for calculating a temperature change rate Tr '; S11 step of comparing the calculated temperature change rate (Tr ') by measuring the set temperature change rate (Tr) and the internal temperature (Tn); As a result of the determination in step S11, if the temperature change rate Tr 'calculated by measuring the internal temperature Tn is smaller than the set temperature change rate Tr, the procedure proceeds to step S18, and the internal temperature is greater than the set temperature change rate Tr. If the temperature change rate (Tr ') calculated by measuring Tn) is the same or greater, it is determined in step S12 that abnormal heating has occurred inside the connection panel; Includes (n used here is defined as a set of natural numbers).

Step S13 for setting smoke value S for warning after detecting smoke generation inside the connection panel; Step S14 for measuring smoke (S ') using a smoke detector; Step S15 comparing whether the set smoke S and the measured smoke S 'are the same; As a result of the determination in step S15, if the set smoke (S) and the measured smoke (S ') are different, the procedure is carried out to step S18, and if the set smoke (S) and the measured smoke (S') are the same, inside the connection panel Step S16, which determines that smoke has occurred; Based on the smoke detection state, the high temperature state, and the abnormal heat generation state, it is determined that a fire has occurred while the smoke detection state is high temperature or abnormal heating, and if none of the smoke detection, high temperature state, or abnormal heating occurs, a fire does not occur. S17 step of determining a simple abnormal state; As a result of the determination in step S17, if it is not in a fire state, step S19 is determined as an abnormal state (dangerous stage 1); The result of the determination in step S17, in the event of a fire, step S20 in which a fire is generated (dangerous stage 2).

The present invention made as described above accurately observes the temperature change through the constant temperature and differential algorithms of the temperature inside the connection panel, and accurately detects the occurrence of a fire through smoke detection, and quickly uses fire extinguishing gas in the event of a fire. Evolution is possible.

In addition, since the gas is used for the fire extinguishing agent sprayed on the electrical and electronic devices for fire extinguishing, even if the device malfunctions and the fire extinguishing agent is sprayed, damage caused by the fire extinguishing agent can be minimized.

In addition, when the gas injected to extinguish the fire is injected locally to the flame, the direction of the flame affected by this may change, so that the fire may spread, so to prevent this, it must be sprayed uniformly inside the connection panel, For this, the distance from the gas storage tank to each nozzle must be kept the same.

1 is a configuration diagram of a photovoltaic device having a fire extinguishing system using gas.
2 is a block diagram of a fire extinguishing system using gas according to an embodiment of the present invention.
Figure 3 is an operation flow chart showing the operation of the solar power generation apparatus with a gas fire extinguishing system according to an embodiment of the present invention.
4 is an operation flowchart showing the determination of the risk level of the solar power generation apparatus having a fire extinguishing system using gas according to an embodiment of the present invention.
Figure 5 shows the flame (a) when there is no gas injection, when the CO ₂ gas is injected non-uniformly, shows the flame (b), when the CO ₂ gas is injected at a uniform pressure on the front , Shows the flame (c).
Figure 6 shows an example of the injection system according to an embodiment of the present invention is composed of a Y fitting (a), a circular pipe (b) and a square tube (c).

1 is a block diagram of a solar power generation system equipped with a gas fire extinguishing system, and FIG. 2 is a block diagram of a gas fire extinguishing system.

According to FIG. 1, a plurality of solar cell arrays 110 are connected in parallel. The solar cell array 110 is a circuit in which a plurality of solar cell modules are connected in series and combined into one to satisfy a predetermined output voltage. In addition, each solar cell module is a plurality of solar cell cells are connected in series and parallel.

The solar cell array 110 generates a DC voltage and generates a current. The generated power flows along a closed circuit between the solar cell array 110, the connection panel 120, and the inverter 130.

The connection panel 120 is composed of a fire extinguishing system 200 using a gas, a fuse unit 160, a high voltage PCB 170, and a breaker 180. Here, the fire extinguishing system 200 using CO ₂ gas includes a communication device and a control unit 150, a smoke detector 210, a temperature sensor 220, a gas storage tank 230, an injection system 240, and a valve 250. Consists of. In addition, the high-voltage PCB 170 is composed of a current measuring unit 171, a voltage measuring unit 172.

According to FIG. 2, the communication device and the control unit 150 in the fire extinguishing system using gas receive data measured from the smoke detector 210 and the temperature sensor 220 to calculate and store the data.

In addition, based on the temperature measured by the temperature sensor 220, a high temperature state is determined by a constant temperature temperature algorithm, and an abnormal heat generation state is determined by a differential temperature algorithm.

The fire is judged in the smoke detection state, the high temperature state, and the abnormal heating state, and the valve 250 is controlled, and information is transmitted to the external monitoring system 140.

Hereinafter, an operating state of fire extinguishing of a photovoltaic device equipped with a fire extinguishing system using gas for carrying out the present invention will be described in detail with reference to FIGS. 3 and 4.

As shown in FIG. 3, first, data measurement and risk steps are calculated (S100).

Subsequently, it is determined whether the abnormal state (dangerous step 1) is correct (S200).

As a result of the determination in step S200, when an abnormal condition (dangerous stage 1) is correct, a device alarm and a monitoring warning window is generated (S300).

On the other hand, if the result of the determination in step S200 is not an abnormal state (dangerous step 1), it is determined whether the fire occurrence state (dangerous step 2) is correct (S400).

As a result of the determination in step S400, if the fire is not in a state of occurrence (dangerous stage 2), it is determined as a normal state (dangerous stage 0) (S500), and the procedure is carried out to S100.

On the other hand, as a result of the determination in step S400, when the fire occurrence state (dangerous stage 2) is correct, a device alarm, a monitoring warning window, and a warning sound are generated. (S600)

Subsequently, a valve located between the digestion gas storage tank and the injection system is opened (S700).

Subsequently, the extinguishing gas is injected through the injection system (S800).

Subsequently, a message about the fire occurrence state (dangerous step 2) is transmitted to the administrator (S900).

As shown in FIG. 4, as an embodiment of the present invention, the temperature measurement sequence (tn) and the measured temperature (Tn) correspond one-to-one, and n is defined as consisting of a set of natural numbers (S1).

Subsequently, when a temperature-related abnormality occurs in the connection panel, a constant temperature type Tf and a differential temperature change rate Tr for warning are set (S2).

Subsequently, the temperature T 'is measured using a temperature sensor installed inside the connection panel (S3).

Subsequently, the measurement sequence number tn is set to n, and n is a natural number increasing from 1 (S4).

The temperature T 'measured in step S3 is stored in Tn (S5).

It is determined whether the measured temperature Tn is greater than or equal to the set constant temperature temperature Tf (S6).

As a result of the determination in step S6, when the measured temperature Tn is greater than or equal to the set constant temperature temperature Tf, it is determined that the inside of the connection panel is in a high temperature state (S7).

On the other hand, as a result of the determination in step S6, when the measured temperature Tn is smaller than the set constant temperature temperature Tf, the procedure is performed in step S18, which is a normal state (dangerous step 0).

It is determined whether the natural number n used for the measurement sequence number (tn) and the stored temperature (Tn) is greater than 5 (S8).

As a result of the determination in step S8, if n is less than or equal to 5, the number of n is increased by 1, and the procedure is executed in step S3 (S9).

On the other hand, as a result of the determination in step S8, if n is greater than 5, the temperature change rate Tr 'is calculated (S10).

Next, it is determined whether the calculated temperature change rate Tr 'is greater than or equal to the set differential temperature change rate Tr (S11).

As a result of the determination in step S11, when the calculated temperature change rate Tr 'is greater than or equal to the set differential temperature change rate Tr, it is determined that abnormal heating has occurred inside the connection panel (S12).

On the other hand, as a result of the determination in step S11, when the calculated temperature change rate Tr 'is smaller than the set differential temperature change rate Tr, the procedure is performed in step S18, which is a normal state (dangerous step 0).

After detecting the occurrence of smoke inside the connection panel, the smoke value (S) for warning is set (S13).

Next, smoke (S ') inside the connection panel is measured using a smoke detector (S14).

Next, it is determined whether the measured smoke S 'and the set smoke S are the same (S15).

As a result of the determination in step S15, if the measured smoke S 'and the set smoke S are the same, it is determined that smoke has occurred inside the connection panel (S16).

On the other hand, as a result of the determination in step S15, when the measured smoke (S ') and the set smoke (S) are different, the procedure is carried out to step S18, which is a normal state (dangerous step 0).

Based on the smoke detection state, the high temperature state, and the abnormal heat generation state, if the smoke detection state is high temperature or abnormal heat, it is judged as a fire, and if none of the smoke detection, high temperature state, or abnormal heat occurs, a fire does not occur. It is determined as a simple abnormal state (S17).

As a result of the determination in step S17, if it is not a fire, it is determined as an abnormal state (dangerous stage 1) (S19).

On the other hand, as a result of the determination in step S17, in the event of a fire, it is determined as a fire occurrence state (dangerous stage 2) (S20).

FIG. 5 shows the effect of uniform injection of gas on the flame, and FIG. 6 is an example of an injection system for uniformly spraying gas inside the connection panel.

As shown in FIG. 5, when there is no fluid flow such as gas injection, the flame (a) is shown, and when the CO ₂ gas is injected at a non-uniform pressure from the injection system above the connection panel into the connection panel, It shows that the flame located on the side where the pressure is relatively weak is not extinguished (b), compared to the side where the pressure is strongly injected, and there is a fear of spreading the flame to the surroundings.

Finally, it shows that the flame is extinguished (c) by the injection of extinguishing gas of uniform pressure from the injection system on the top of the connection panel into the connection panel.

According to FIG. 6, the injection system can be manufactured in various forms, and shows an example produced using materials such as a Y fitting (a), a circular pipe (b), and a tube (c).

In addition, in order to inject the gas at a uniform pressure (p ') inside the connecting panel, the cross-sectional area (s) of the nozzle and the moving distance (l) of the gas in the injection system must be the same as in Equation 1 below.

It is assumed that the gas flowing inside the injection system is in an ideal state.

When Y fitting (a) is used, a pipe made of heat-resistant and fire-resistant material is used. Since the cross-sectional area of the pipe is the same, the pressure at the nozzle is maintained if the distance from the gas inlet to the nozzle of the injection system is kept constant. same.

Also, in the case of the circular pipe (b) and the limelight (c), since the cross-sectional area inside the tube is the same, and the nozzle is calculated by calculating the shortest distance from the inlet to the nozzle of the fire extinguishing gas of the injection system, the nozzle is ejected. The gas pressure is the same.

100: solar power generation system 110: solar cell array
120: connection panel 130: inverter
140: monitoring system 150: communication device and control unit
151: operation unit 152: communication unit
153: control unit 160: fuse unit
170: high voltage PCB 171: current measuring unit
172: voltage measuring unit 180: circuit breaker
200: gas extinguishing system 210: smoke detector
220: temperature sensor 230: gas storage tank
240: injection system 250: valve

Claims (9)

A plurality of solar cell arrays generating a DC voltage and generating current;
A fuse unit in which DC voltages generated by the plurality of solar cell arrays are merged and supplied to an inverter and connected in series to each input / output terminal of the plurality of solar cell arrays;
A high voltage PCB having a voltage measuring unit measuring voltage at each output terminal of the fuse and a current measuring unit measuring current at each output terminal of the fuse;
The temperature sensor inside the connection panel measures the temperature inside the connection panel, the smoke sensor detects smoke generated inside the connection panel, and determines the fire through the high temperature, abnormal heating condition, and smoke detection determined by the internal temperature. A gas fire extinguishing system for extinguishing a fire by the judgment of the communication device and the control unit and the communication device and control unit for generating a control signal for opening and closing the valve and alerting the user of the city valve;
A gas storage tank in which gas used for extinguishing is stored in the gas extinguishing system;
A valve for opening and closing between the gas storage tank and the injection system according to the control signals of the communication device and the control unit in the gas fire extinguishing system;
An injection system for injecting extinguishing gas at a uniform pressure into the connection panel in the gas extinguishing system;
A circuit breaker blocking a closed circuit between the solar cell array and the inverter;
An inverter that converts DC current supplied from the connection panel into AC current;
It includes; a monitoring system for monitoring the operation status and the presence or absence of the solar cell array, the connection panel and the inverter;
The communication device and control unit transmits data on the output of the photovoltaic device and the state of the connection panel to the monitoring system based on the smoke detection and abnormal heat generation or the high temperature state, and the abnormal state determined by the calculation unit ( High temperature, abnormal heat, smoke detection), the monitoring system controls the opening and closing of the valve existing between the gas storage tank and the injection system, and controls the temperature and If it is determined that a fire has occurred inside the connection panel based on the smoke data, and includes a control unit that controls to open the valve to extinguish the fire,
The calculating unit determines the high temperature state by using the constant temperature algorithm for the internal temperature measured inside the connection panel, calculates the temperature change rate by using the differential algorithm for the measured internal temperature, and determines abnormal heat, and the inside of the connection panel by the smoke detector. Judges the abnormal state according to whether smoke is generated, determines the fire based on the smoke detection and abnormal heat or high temperature,
A photovoltaic power generation system equipped with a fire extinguishing system using gas, characterized in that the cross-sectional area of the nozzle and the moving distance of the gas are the same in the injection system to inject the gas at a uniform pressure inside the connection panel. delete delete The method according to claim 1,
The injection system uses a gas characterized by equalizing the pressure injected from each nozzle by maintaining the same distance from the gas storage tank to the injection nozzle so that the fire extinguishing gas can be injected at a uniform pressure inside the connection panel. Solar power system with fire extinguishing system. The method according to claim 1,
A gas-based fire extinguishing system further comprising a meteorological observation panel installed around the plurality of solar cell arrays to obtain temperature information and solar radiation information, and data obtained weather information is transmitted to the monitoring system. Solar power system. The method according to claim 1,
In the case of using the Y fitting, the injection system uses a tube made of a material having heat resistance and fire resistance, and the inside of the tube has the same cross-sectional area and maintains a constant distance from the gas inlet to the nozzle of the injection system. Solar power generation system with fire extinguishing system. delete When the internal temperature of the connection panel is a measurement sequence number (tn), the measured temperature (Tn), the measurement sequence number and the measured temperature in a one-to-one correspondence step S1;
S2 step of setting a constant temperature type (Tf) and a differential temperature change rate (Tr) for warning when a temperature-related abnormality occurs in the connection panel;
Step S3 for measuring the internal temperature (T ') with a temperature sensor installed inside the connection panel; n increases from 1, the measurement sequence number (tn) is set to n step S4;
Step S5 of storing the measured temperature T 'in Tn;
Step S6, determining whether the measured temperature Tn is greater than or equal to the set constant temperature temperature Tf;
As a result of the determination in step S6, when the measured temperature Tn is smaller than the set constant temperature temperature Tf, the procedure is performed in step S18, which is a normal state (dangerous step 0), and the measured temperature Tn is the set constant temperature. When the temperature is greater than or equal to the temperature (Tf), step S7 for determining the inside of the connection panel as a high temperature state;
Step S8 to determine whether the measurement sequence number n is greater than 5;
As a result of the determination in step S8, when n is equal to or less than 5, step S9 of increasing the measurement sequence n by 1;
As a result of the determination in step S8, if n is greater than 5, step S10 for calculating a temperature change rate Tr ';
Step S11 comparing the calculated temperature change rate Tr and the calculated temperature change rate Tr 'by measuring the internal temperature Tn;
As a result of the determination in step S11, if the temperature change rate Tr 'calculated by measuring the internal temperature Tn is smaller than the set temperature change rate Tr, the procedure is carried out to step S18, which is a normal state (dangerous step 0), and the set temperature. Step S12, which determines that abnormal heating has occurred inside the connection panel when the temperature change rate Tr 'calculated by measuring the internal temperature Tn is greater than or equal to the change rate Tr; Includes,
Step S13 for setting smoke value S for warning after detecting smoke generation inside the connection panel;
Step S14 for measuring smoke S 'using a smoke detector;
Step S15 comparing whether the set smoke S and the measured smoke S are the same;
As a result of the determination in step S15, if the set smoke (S) and the measured smoke (S ') are different, the procedure is performed in step S18, which is a normal state (dangerous phase 0), and the set smoke (S) and the measured smoke (S'). If is the same, step S16 determining that smoke has occurred inside the connection panel;
Based on the smoke detection state, the high temperature state, and the abnormal heat generation state, if the smoke detection state is high temperature or abnormal heat, it is judged as a fire, and if none of the smoke detection, high temperature state, or abnormal heat occurs, a fire does not occur. S17 step of determining a simple abnormal state;
As a result of the determination in step S17, if it is not a fire state, step S19 is determined as an abnormal state (dangerous stage 1);
As a result of the determination in step S17, in the event of a fire, step S20 in which a fire is generated (dangerous stage 2).
(N used here is defined as a set of natural numbers) delete

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